Transcriptomics using lung resection material to advance our understanding of COPD and idiopathic pulmonary fibrosis pathogenesis

Extract COPD and idiopathic pulmonary fibrosis (IPF) are both chronic lung diseases with distinct pathologies. COPD is characterised by progressive airflow obstruction and encompasses emphysema leading to loss of alveolar structure and chronic bronchitis including inflammation [1]. IPF is a progressive fatal interstitial lung disease without effective treatment, characterised by fibrosis of the lung [2]. Risk factors such as smoking and symptoms such as shortness of breath are common to both. Although the clinical features are well defined and categorised, the differences and similarities between mechanistic pathways have not been fully investigated.

IPA results from the control versus COPD gene expression dataset showed a small number of associations possibly due to the small number of differentially expressed genes and the individual subject heterogeneity in the heatmap (figure 1d).Only the wound healing signalling pathway and upstream regulators SORL1 and CG were seen to be activated with a z-score >2 (data not shown).No pathways or regulators were found to be inhibited and there were no strongly linked diseases apart from those related to cancer.
IPA results from the control versus IPF dataset showed a greater number of associations.Pathways such as peroxisome proliferator-activated signalling, xenobiotic metabolism and cell cycle-related mechanisms were activated, and all had z-scores >2 (figure 1e, only top 10 pathways shown).There were a larger number of inhibited pathways such as those involved cytokine signalling (IL8, IL17 and IL6), nitric oxide signalling, white blood cell signalling (natural killer cells and macrophages, which all had z-scores <2) (figure 1e, only top 10 pathways shown).Furthermore, there were also associations with disease, such as IPF ( p=9.23×10 −18 ), chronic pulmonary disease ( p=3.71×10 07 ), fibrosis (p=6.54×10−19 ) and cardiac hypertrophy ( p=1.15×10 −4 ).>60% of disease associations were cancer related (data not shown).
In the IPF dataset, upstream regulators or factors such as COL18A1 and IL1RN were predicted to be active compared to factors such as STAT1, IFNG and IL12B, which were inhibited in the IPF tissue (figure 1f ).Most inhibited factors tended to be transcription regulators or cytokines.
Investigation of the overlap between the COPD and IPF gene expression datasets showed that there were 60 common genes representing 44% of the total differentially expressed genes from the control versus COPD comparison and 2.4% of the total differentially expressed genes in the control versus IPF comparison (figure 1g).Of these, 31 genes were upregulated in both diseases such as COL31A1, COL1A1 and IL13RA2 and 29 genes were down regulated in both diseases such as MME, DNAJC27 and KIFC3.There were no genes which were common to both datasets but showed gene expression in opposite directions.
IPA on overlapping genes showed processes such as "apoptosis" ( p=0.002), "extracellular matrix organisation" ( p=3.89 x10 −4 ) and "necrosis" ( p=0.001) were associated with the common upregulated genes, and processes such as "infection by RNA virus" ( p=0.024) and "cell junction organisation" ( p=0.005) were associated with the common downregulated genes."Chronic inflammatory disorder" ( p=0.015) was associated with both down-and upregulated genes, suggesting these may be common pathways/mechanisms to both diseases.
Interestingly, pathways involved in rheumatic disease ( p=0.015) appeared to be associated only with genes differentially upregulated in the control versus COPD dataset (CYP7B1, DPYS, HTRA1, IGFBP7, IGHD, SNAI2 and TMEM266), indicating genes in this pathway may be unique to COPD lung tissue and/or that rheumatic disease and COPD are strongly linked comorbidities.Over 100 common upstream regulators were identified, of which >70% had either COL1A1 or COL3A1 as their target molecule, indicating collagen is a key factor in both diseases, supporting evidence from previous studies [6,7].There were no upstream regulators identified by IPA that were unique to the COPD or IPF gene dataset.
(z-score <2) upstream regulators ( p<0.05).g) Overlapping genes between the differential expression analysis for the control versus COPD and control versus IPF datasets.FEV 1 : forced expiratory volume in 1 s; FVC: forced vital capacity; FC: fold change; # : Chi-squared test; ¶ : one-way ANOVA.https://doi.org/10.1183/23120541.00061-2024 This study aimed to further our mechanistic understanding of COPD and IPF via transcriptomics using lung resection tissue.Importantly, we show that there is a subset of genes that are differentially expressed in the same direction in both IPF and COPD, suggesting common causal pathways with associated opportunities for therapeutic intervention.In the COPD-specific analyses, we could not provide significant insight due to the small number of differentially expressed genes and inconclusive IPA, although a general increase in matrix-associated protein and growth regulator gene expression was seen and there was a strong link to rheumatic disease.This link has been extensively reported [8] and the genes highlighted in our study may provide novel avenues of exploration.The IPF-specific analyses supported previous literature with regards to increases in expression levels of genes implicated in IPF pathogenesis (e.g.elevated levels of keratins, collagens, mucins and MMPs) and, importantly, identified other genes for additional study [9][10][11][12].
Although this study would benefit from a larger discovery and a replication cohort due to its modest sampling, and while donor heterogeneity, especially in the COPD tissue, and incomplete comorbidity and medication data limit our ability to fully define common/different pathways between COPD and IPF, this study highlights some potential mechanistic pathways that are involved in both COPD and IPF, such as apoptosis, necrosis, chronic inflammation and viral infection.Similarly, the IPF analyses identified genes involved in transcriptional regulation and inflammation, supporting previously associated factors/pathways, such as MMPs and fibrosis.This study also provides confirmation of pathways and genes unique to COPD, which are involved in other diseases such as rheumatic disease.This study provides a foundation for further in-depth study of distinct and overlapping pathways contribution to these difficult to treat diseases.

FIGURE 1
FIGURE 1 Donor information, differential gene expression and pathway analysis changes between control, COPD and idiopathic pulmonary fibrosis (IPF) groups.a) Tissue donor demographic information and analysis.Volcano plots and corresponding heatmaps for differential gene expression analysis between b) control and COPD and c) control and IPF groups with d) corresponding heatmaps.Results were corrected for donor age, sex, smoking history and RNA extraction batch, and adjusted using the Benjamini-Hochberg procedure (false discovery rate 5%; p<0.05).e) Ingenuity pathway analysis (IPA) for the control versus IPF differential gene expression dataset showing top activated (z-score >2, orange) and inhibited (z-score <2, blue) pathways.f) IPA for the control versus IPF differential gene expression dataset showing activated (z-score >2) and inhibited